/*
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* Copyright (C) 2020 Christopher J. Howard
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*
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* This file is part of Antkeeper source code.
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*
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* Antkeeper source code is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* Antkeeper source code is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with Antkeeper source code. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "celestial-mechanics.hpp"
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#include "math/angles.hpp"
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#include <cmath>
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namespace ast
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{
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double approx_ecliptic_obliquity(double jd)
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{
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return math::radians<double>(23.4393 - 3.563e-7 * (jd - 2451545.0));
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}
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double3 approx_sun_ecliptic(double jd)
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{
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const double t = (jd - 2451545.0) / 36525.0;
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const double m = 6.24 + 628.302 * t;
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const double longitude = 4.895048 + 628.331951 * t + (0.033417 - 0.000084 * t) * std::sin(m) + 0.000351 * std::sin(m * 2.0);
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const double latitude = 0.0;
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const double distance = 1.000140 - (0.016708 - 0.000042 * t) * std::cos(m) - 0.000141 * std::cos(m * 2.0);
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double3 ecliptic;
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ecliptic.x = distance * std::cos(longitude) * std::cos(latitude);
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ecliptic.y = distance * std::sin(longitude) * std::cos(latitude);
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ecliptic.z = distance * std::sin(latitude);
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return ecliptic;
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}
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double3 approx_moon_ecliptic(double jd)
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{
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const double t = (jd - 2451545.0) / 36525.0;
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const double l1 = 3.8104 + 8399.7091 * t;
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const double m1 = 2.3554 + 8328.6911 * t;
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const double m = 6.2300 + 628.3019 * t;
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const double d = 5.1985 + 7771.3772 * t;
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const double d2 = d * 2.0;
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const double f = 1.6280 + 8433.4663 * t;
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const double longitude = l1
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+ 0.1098 * std::sin(m1)
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+ 0.0222 * std::sin(d2 - m1)
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+ 0.0115 * std::sin(d2)
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+ 0.0037 * std::sin(m1 * 2.0)
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- 0.0032 * std::sin(m)
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- 0.0020 * std::sin(d2)
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+ 0.0010 * std::sin(d2 - m1 * 2.0)
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+ 0.0010 * std::sin(d2 - m - m1)
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+ 0.0009 * std::sin(d2 + m1)
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+ 0.0008 * std::sin(d2 - m)
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+ 0.0007 * std::sin(m1 - m)
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- 0.0006 * std::sin(d)
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- 0.0005 * std::sin(m + m1);
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const double latitude = 0.0895 * sin(f)
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+ 0.0049 * std::sin(m1 + f)
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+ 0.0048 * std::sin(m1 - f)
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+ 0.0030 * std::sin(d2 - f)
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+ 0.0010 * std::sin(d2 + f - m1)
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+ 0.0008 * std::sin(d2 - f - m1)
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+ 0.0006 * std::sin(d2 + f);
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const double r = 1.0 / (0.016593
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+ 0.000904 * std::cos(m1)
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+ 0.000166 * std::cos(d2 - m1)
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+ 0.000137 * std::cos(d2)
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+ 0.000049 * std::cos(m1 * 2.0)
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+ 0.000015 * std::cos(d2 + m1)
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+ 0.000009 * std::cos(d2 - m));
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double3 ecliptic;
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ecliptic.x = r * std::cos(longitude) * std::cos(latitude);
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ecliptic.y = r * std::sin(longitude) * std::cos(latitude);
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ecliptic.z = r * std::sin(latitude);
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return ecliptic;
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}
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double3x3 approx_moon_ecliptic_rotation(double jd)
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{
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const double t = (jd - 2451545.0) / 36525.0;
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const double l1 = 3.8104 + 8399.7091 * t;
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const double f = 1.6280 + 8433.4663 * t;
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const double az0 = f + math::pi<double>;
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const double ax = 0.026920;
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const double az1 = l1 - f;
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double3x3 rz0 =
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{
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cos(az0), -sin(az0), 0,
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sin(az0), cos(az0), 0,
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0, 0, 1
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};
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double3x3 rx =
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{
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1, 0, 0,
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0, cos(ax), -sin(ax),
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0, sin(ax), cos(ax)
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};
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double3x3 rz1 =
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{
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cos(az1), -sin(az1), 0,
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sin(az1), cos(az1), 0,
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0, 0, 1
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};
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return rz0 * rx * rz1;
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}
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} // namespace ast
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